Injection stretch blow molding method and apparatus for producing internally threaded containers

ABSTRACT

A carrier assembly for injection molding a parison with internal threads. The carrier assembly may be used with an injection stretch blow molding machine that includes a core rod. The carrier assembly comprises a carrier insert surrounding a portion of the core rod. The carrier insert includes a thread-forming portion presenting an interior radial surface and an exterior radial surface. The interior radial surface is configured to be positioned adjacent to the core rod, and the exterior radial surface includes a threaded protrusion configured to extend away from the core rod. The carrier assembly also includes a pinion insert surrounding at least a portion of the threaded protrusion of the thread-forming portion of the carrier insert. The pinion insert is spaced apart from the thread-forming portion of the carrier insert so as to present a thread-forming cavity between the pinion insert and the carrier insert.

RELATED APPLICATION

This U.S. patent application is a continuation-in-part application of,and claims priority benefit to, co-pending U.S. patent application Ser.No. 14/788,105, filed on Jun. 30, 2015, and entitled “INJECTION STRETCHBLOW MOLDING METHOD AND APPARATUS FOR PRODUCING INTERNALLY THREADEDCONTAINERS,” which claims priority to U.S. Provisional PatentApplication Ser. No. 62/019,468, filed on Jul. 1, 2014, and entitled“ISBM METHOD AND APPARATUS FOR PRODUCING INTERNALLY THREADEDCONTAINERS.” The entirety both above-identified prior-filed patentapplications are incorporated herein by reference.

BACKGROUND OF THE INVENTION 1. Field of the Invention

Embodiments of the present invention relate to an injection stretch blowmolding method and apparatus for producing internally threadedcontainers.

2. Description of the Related Art

Injection stretch blow molding (ISBM) is a technique used for creatingvarious containers such as plastic bottles. The ISBM process isperformed with an ISBM machine that first injection molds a resin into aplurality of parisons of desired shapes, conditions the parisons inpreparation for stretch blow molding, stretch blow molds the parisonsinto the final molded articles, and then ejects the molded articles fromthe ISBM machine. ISBM machines generally include two types, 3-stage or4-stage. The 4-stage ISBM machines may broadly comprise an injectionstation for injection molding the resin into the parisons, aconditioning station for processing the parisons (e.g., applying heatand/or cooling to the parisons), a stretch blow station for stretch blowmolding the parisons into the final molded articles, an ejection stationfor ejecting the molded articles from the ISBM machine, and a rotationplate for transferring the parisons and the molded articles between thestations of the ISBM machine. The 3-stage ISBM machine differs from the4-stage machine in that the 3-stage machine will not include aconditioning station.

Typically, the molded articles formed by the ISBM machine arecontainers. Such containers are often manufactured in the form ofplastic bottles, with such bottles having a main body and a neckextending up from the main body. The necks will include threadedexterior surfaces for securing lids or caps to the containers. The lidsor caps serve to seal the containers and their contents. In certaininstances, it would be preferable to manufacture containers that includenecks with threaded interior surfaces, such that lids or caps could besecured to the container via the threaded interior surfaces. Suchinternally threaded containers may be beneficial because they can createbetter seals and/or can minimize or alleviate leakages. Additionally,containers with internal threads may provide for smooth outer surfaces,which can be more aesthetically pleasing.

Thus, it would be desirable to have an ISBM machine and method forproducing molded articles (e.g., containers) with internal threads, suchthat the molded articles can be sealed via the internal threads.

SUMMARY

Embodiments of the present invention include a carrier assembly forinjection molding a parison with internal threads. The carrier assemblymay be used with an injection stretch blow molding machine that includesa core rod. The carrier assembly comprises a carrier insert surroundinga portion of the core rod. The carrier insert includes a thread-formingportion presenting an interior radial surface and an exterior radialsurface. The interior radial surface is configured to be positionedadjacent to the core rod, and the exterior radial surface includes athreaded protrusion configured to extend away from the core rod. Thecarrier assembly also includes a pinion insert surrounding at least aportion of the threaded protrusion of the thread-forming portion of thecarrier insert. The pinion insert is spaced apart from thethread-forming portion of the carrier insert so as to present athread-forming cavity between the pinion insert and the carrier insert.

Embodiments of the present invention additionally include ejectionstation tooling for an injection stretch blow molding machine. Theejection station tooling is configured for ejecting aninternally-threaded molded article from a carrier assembly. The ejectionstation tooling comprises a base and an actuation assembly associatedwith the base. The actuation assembly includes a plate configured toactuate in a first dimension and a bar configured to actuate in a seconddimension in response to the actuation of the plate. The ejectionstation tooling is operable to remove the molded article from thecarrier assembly by causing the molded article to rotate with respect toa portion of the carrier assembly.

Embodiments of the present invention further include a method of makingan internally-threaded stretch blow molded article. The method includesthe initial step of injection molding a resin to form at least oneparison at an injection station. During the injection step, the parisonis formed by injecting the resin into a thread-forming cavity defined bya carrier assembly. The carrier assembly comprises a carrier insertincluding a thread-forming portion presenting an exterior radial surfacehaving a threaded protrusion. The carrier assembly further comprises apinion insert surrounding at least a portion of the threaded protrusionof the thread-forming portion of the carrier insert, with the pinioninsert being spaced apart from the thread-forming portion so as topresent the thread-forming cavity. An additional step includestransferring the parison, via the carrier assembly, to a stretch blowstation. An additional step includes stretch blow molding the parisoninto a molded article at the stretch blow station. An additional stepincludes transferring the molded article, via the carrier assembly, toan ejection station. An additional step includes ejecting the parisonfrom the carrier assembly at the ejection station. During the ejectingstep, the ejection station causes a rotation of the molded article withrespect to at least a portion of the carrier assembly, such that themolded article is removed from the carrier assembly.

Embodiments of the present invention yet further include a stretch blowmolded article comprising an article body stretch blown from a parison,and an article neck extending from the article body and presenting anopening for fluidly coupling an exterior of the molded article to aninterior of the article body. The article neck includes an interiorradial surface an exterior radial surface, and the interior radialsurface includes threads formed thereon.

Embodiments of the present invention further include ejection stationtooling for an injection stretch blow molding machine. The ejectionstation tooling comprises a carrier plate and a plurality of carrierassemblies secured to the carrier plate, with each of the carrierassemblies being configured to carry an internally-threaded moldedarticle. The ejection station tooling additionally comprises anactuation assembly configured to remove each of the molded articles fromits respective carrier assembly by causing the molded article to rotatewith respect to a portion of its carrier assembly

Embodiments of the present invention further include ejection stationtooling for an injection stretch blow molding machine. The ejectionstation tooling comprises a carrier plate, and a plurality of carrierassemblies secured to the carrier plate, with each of the carrierassemblies being configured to carry an internally-threaded moldedarticle. The ejection station tooling additionally comprises a rotationassembly integrated with the carrier plate. The rotation assembly isconfigured to remove each of the molded articles from its respectivecarrier assembly by causing the molded article to rotate with respect toa portion of its carrier assembly.

Embodiments of the present invention further include a method ofejecting an internally-threaded molded article from an injection stretchblow molding machine. The internally-threaded molded article is securedin place by a carrier assembly. The method comprises the step ofshifting a drive mechanism into engagement with a rotation assembly. Anadditional step includes causing one or more components of said rotationassembly to rotate. A further step includes imparting rotation from therotation assembly to a first portion of the carrier assembly. During theimparting step, the molded article is disengaged from the carrierassembly by causing the molded article to rotate with respect to asecond portion of the carrier assembly.

This summary is provided to introduce a selection of concepts in asimplified form that are further described below in the detaileddescription. This summary is not intended to identify key features oressential features of the claimed subject matter, nor is it intended tobe used to limit the scope of the claimed subject matter. Other aspectsand advantages of the present invention will be apparent from thefollowing detailed description of the embodiments and the accompanyingdrawing figures.

BRIEF DESCRIPTION OF THE DRAWING FIGURES

Embodiments of the present invention are described in detail below withreference to the attached drawing figures, wherein:

FIG. 1a is a perspective view of an injection stretch blow moldingmachine;

FIG. 1b is a top plan view of the machine from FIG. 1 a;

FIG. 1c is a side elevational view of the machine from FIGS. 1a and 1 b;

FIG. 2 is a cross-section of a carrier assembly and a core rodassociated with an injection mold;

FIG. 3 is a cross-section of the carrier assembly, the core rod, and theinjection mold from FIG. 2, with resin having been injected into themold to form a parison;

FIG. 4 is a partial perspective view of the carrier assembly and parisonfrom FIG. 3, with a portion of the carrier assembly and the parison cutaway;

FIG. 5 is a top exploded view of the carrier assembly and parison fromFIG. 4;

FIG. 6 is a bottom exploded view of the carrier assembly and parisonfrom FIGS. 4-5;

FIG. 7 is a perspective view of a molded article with internal threadsmade according to embodiments of the present invention;

FIG. 8 is a cross-section of the molded article from FIG. 7;

FIG. 9 is a front perspective view of ejection station tooling accordingto embodiments of the present invention, with part of a bottom portionof the tooling cut away to particularly show a cam plate and a rack, aswell as to shown the carrier assembly from FIGS. 4-6 being associatedwith the ejection station tooling;

FIG. 10 is a partial side exploded view of the ejection station toolingfrom FIG. 9, with a top portion of the tooling cutaway;

FIG. 11 is a bottom rear perspective view of the tooling from FIGS.9-10, with part of the bottom portion of the tooling removed toparticularly shown the cam plate the rack, and a roller, as well as toshow the carrier assembly from FIGS. 4-6;

FIG. 12 is a partial side perspective view of the tooling from FIGS.9-11, with a portion of the tooling cutaway to particularly show the camplate operable to actuate in a first dimension, the roller and the rackoperable to actuate in the second dimension, and a portion of thecarrier assembly configured to rotate in response to the actuation ofthe rack;

FIG. 13 is an additional partial side perspective view of the toolingfrom FIGS. 9-12, with a portion of the tooling cutaway to particularlyshow a molded article being rotated in response to the rotation of theportion of the carrier assembly;

FIG. 14 is an additional partial side perspective view of the toolingfrom FIG. 13, with the portion of the tooling cutaway to particularlyshow the molded article being ejected in response to the rotation of theportion of the carrier assembly;

FIG. 15 is a partial side perspective view of ejection station toolingaccording to embodiments of the present invention, particularly showinga carrier assembly with bearing elements positioned between a carrierinsert and a pinion insert;

FIG. 16 is a bottom exploded view of the carrier assembly and portionsof the tooling from FIG. 15;

FIG. 17 is a front perspective view of ejection station toolingaccording to another embodiment of the present invention, with theejection station tooling configured for removing internally-threadedmolded articles from carrier assemblies;

FIG. 18 is a bottom perspective view of the ejection station toolingfrom FIG. 17, illustrating a carrier plate supporting a plurality ofcarrier assemblies, with each of the carrier assemblies supporting aninternally-threaded molded article;

FIG. 19 is another bottom perspective view of the ejection stationtooling from FIGS. 17 and 18, with a bottom portion of the carrier plateremoved to illustrate the rotation assembly comprising a plurality ofspur gears;

FIG. 20 is another top perspective view of the ejection station toolingfrom FIGS. 17-19, with bottom portions of the tooling cut away toillustrate the rotation assembly in more detail;

FIG. 21 is another top perspective view of the ejection station toolingfrom FIGS. 17-20, with bottom portions of the tooling cut away toillustrate the rotation assembly in more detail and with a drivemechanism lowered into engagement with one of the spur gears;

FIG. 22 is an enlarged view of the ejection station tooling from FIGS.17-21, with bottom portions of the tooling cut away to illustrateinternally-threaded molded articles being removed from their carrierassemblies;

FIG. 23 is an exploded view of a carrier assembly for supporting aninternally-threaded molded article;

FIG. 24 is a cross section of the carrier assembly from FIG. 23 securedto a carrier plate, and particularly illustrating the carrier assemblysupporting the internally-threaded molded article;

FIG. 25 is a front perspective view of ejection station toolingaccording to yet another embodiment of the present invention, with abottom portion of the tooling cut away to illustrate a rotation assemblyin the form of a worm gear for removing internally-threaded moldedarticles from carrier assemblies;

FIG. 26 is a bottom perspective view of the ejection station toolingfrom FIG. 25, with a bottom portion of a carrier plate cut away toillustrate the rotation assembly in more detail; and

FIG. 27 is another bottom perspective view of the ejection stationtooling from FIGS. 25 and 26, illustrating the rotation assembly beingused to remove the internally-threaded molded articles from theircarrier assemblies.

The drawing figures do not limit the present invention to the specificembodiments disclosed and described herein. The drawings are notnecessarily to scale, emphasis instead being placed upon clearlyillustrating the principles of the invention.

DETAILED DESCRIPTION

The following detailed description of the invention references theaccompanying drawings that illustrate specific embodiments in which theinvention can be practiced. The embodiments are intended to describeaspects of the invention in sufficient detail to enable those skilled inthe art to practice the invention. Other embodiments can be utilized andchanges can be made without departing from the scope of the presentinvention. The following detailed description is, therefore, not to betaken in a limiting sense. The scope of the present invention is definedonly by the appended claims, along with the full scope of equivalents towhich such claims are entitled.

In this description, references to “one embodiment,” “an embodiment,” or“embodiments” mean that the feature or features being referred to areincluded in at least one embodiment of the technology. Separatereferences to “one embodiment,” “an embodiment,” or “embodiments” inthis description do not necessarily refer to the same embodiment and arealso not mutually exclusive unless so stated and/or except as will bereadily apparent to those skilled in the art from the description. Forexample, a feature, structure, act, etc. described in one embodiment mayalso be included in other embodiments, but is not necessarily included.Thus, the present technology can include a variety of combinationsand/or integrations of the embodiments described herein.

Embodiments of the present invention are configured for use with an ISBMmachine, such as ISBM machine 10 illustrated in FIGS. 1a-1c . The ISBMmachine 10 broadly comprises an injection station 12 associated with aninjection nozzle 14, a conditioning station 16, stretch blow station 18,and an ejection station 20. In addition, the ISBM machine 10 may includea rotation plate (not shown) configured to carry a row of thread splitsor the like (not shown in FIGS. 1a-1c ) for transferring the parisonsand/or the molded articles between the stations of the ISBM machine 10.As such, the ISBM machine 10 is operable to inject resin into molds toform a plurality of parisons, and then to stretch blow mold the parisonsinto a plurality of molded articles.

In more detail, the ISBM processes performed with the ISBM machine 10may include the initial step of injecting a thermoplastic resin (e.g.,Polyethylene terephthalate (PET)) within molds at the injection station12 via the nozzle 14 to form one or more parisons. The ISBM process maythen include the next step of actuating the rotation plate to transferthe resulting parisons from the injection station 12 to the conditioningstation 16 such that the parisons can undergo heat treatment or otherconditioning processes. As previously described, some ISBM machines maynot include a conditioning station 16, such that the parisons aretransferred directly from the injection station 12 to the stretch blowstation 18. Regardless, the rotation plate next transfers the parisonsto the stretch blow station 18 to stretch blow the parisons into moldedarticles. Next, the molded articles may be transferred via the rotationplate to the ejection station 20, where the molded articles are ejectedfrom the ISBM machine 10. The injection stretch blow molding processdescribed above may be performed repetitively by the ISBM machine 10.For example, the method steps described herein may be repeated at least100, 1,000, or 10,000 consecutive times.

Beneficially, embodiments of the present invention provide for the ISBMmachine 10 to create parisons with internal threads. Specifically, aswill be described in more detail below, the internal threads may beformed on neck portions of the parisons. Furthermore, once the parisonsare stretch blown, the resulting molded articles will correspondinglyinclude internal threads on neck portions of the molded articles. Assuch, the internal threads formed on the neck portions of the parisonsand/or the molded articles can function as closure components, such thatlids or caps can be secured to the parisons and/or molded articles viathe internal threads.

In more detail, the ISBM machine 10 may, at the injection station 12, beconfigured to inject molten resin (e.g., PET) into a plurality moldcavities formed within a mold to create the parisons. In someembodiments, each of the molds that include a mold cavity may comprise apair of individual mold halves that are configured to split or separatebetween a closed position and an open position. In the closed position,the mold halves cooperate to define the mold cavity. To facilitate thecreation of the parison, and with reference to FIG. 2, an individualcore rod 30 may inserted within an individual mold cavity of a mold 32(e.g., between the mold halves, of which only a single mold half isshown in FIG. 2), such that the core rod 30 and the mold 32cooperatively define a parison-forming cavity 34. As apparent from FIG.2, the parison-forming cavity 34 may be defined as the sub-space or voidwithin the mold cavity that extends between the core rod 30 and theinterior surface of the mold 32. As illustrated in FIG. 3, molten resincan be injected within the parison-forming cavity 34 so as to form ashape corresponding to the mold 32 and the core rod 30. Once the resinsufficiently cools, it will harden to form a parison 36 with the shapecorresponding to the mold 32 and the core rod 30.

To facilitate the production of a parison 36 formed within internalthreads, embodiments of the present invention provide for the core rod30 to be associated with a carrier assembly 40, as shown in FIGS. 2-6,that facilitates the production of such internal threads. Furthermore,in addition to facilitating the manufacture of an internally threadedparison, as described in more detail below, the carrier assembly 40 maybe operable to secure the parison 36 for transport, via the rotationplate, between each stations of the ISBM machine 10. As such, thecarrier assembly 40 may replace thread splits used with standard ISBMmachines.

In more detail, and remaining with FIGS. 2-6, the carrier assembly 40may comprise a carrier insert 42 configured to surround a portion of thecore rod 30. The carrier insert may generally have an annular shapeincluding an inner diameter and an outer diameter. As perhaps best shownin FIGS. 4 and 6, the carrier insert 42 may include a main section 44formed as an annular plate or a ring. The carrier insert mayadditionally comprise thread-forming portion 46 that extends down fromthe main section 44. The thread-forming portion 46 may be formed with aninterior radial surface and an exterior radial surface. As shown inFIGS. 2-3, when the carrier assembly 40 is associated with the core rod30, the interior radial surface of the carrier insert 42 is positionedadjacent to and/or in contact with the core rod 30. Contrastingly, theexterior radial surface extends away from the core rod 30 and comprises,as will be discussed in more detail below, a threaded protrusion 48 thatprotrudes from the exterior radial surface.

In some embodiments, as perhaps best shown in FIGS. 4-5, the carrierinsert 42 may include an annular protrusion 50 extending up from themain section 44. Although the outer diameter of the carrier insert 42may be discontinuous between each of the sections (e.g., between themain section 44, the thread-forming portion 46, and the annularprotrusion 50), the inner diameter of the carrier insert 42 may beconsistent or may vary continuously between the sections. For instance,some embodiments may provide for the inner diameter of the carrierinsert 42 to vary across certain portions of a thickness of the carrierinsert (e.g., from an upper portion of the carrier insert 42 to a lowerportion of the carrier insert 42). For instance, as perhaps best shownin FIG. 4, the inner diameter of the carrier insert 42 may vary linearlyfrom a top portion of the annular protrusion 50 to a bottom portion ofthe main section 44. Such variance may facilitate the ability for thecore rod 30 to be inserted and removed from association with the carrierassembly. However, the inner diameter of the carrier insert 42 may begenerally consistent along at least a portion of the thread-formingportion 46.

The threaded protrusion 48 on the exterior radial surface of thethread-forming portion 46 of the carrier insert 42 may, in someembodiments, be formed with single lead threads, double lead threads,triple lead threads, or other multi-lead threads. For instance, thethreaded protrusion 48 shown in the drawings comprise double leadthreads, which include two leads winding around the exterior radialsurface of the thread forming-portion 46. As such, and with reference toFIG. 6, the leads of the threaded protrusion 48 may each be formed witha lowermost starting point 54 and an uppermost ending point 56. In someembodiments, the lowermost starting points 54 will be located on a planethat bisects the thread-forming portion 46 and that includes alongitudinal axis of the thread-forming portion 46. Additionally, theuppermost ending points 56 may extend along the exterior radial surfaceof the thread-forming portion 46 past the plane that includes thelowermost starting point 54, such that the threads will be truncated attheir lowermost starting points 54.

With reference to FIGS. 2-6, the carrier assembly 40 may furthercomprises a pinion insert 60 that is configured to surround at least aportion of the threaded protrusion 48 of the thread-forming portion 46of the carrier insert 42. In certain embodiments, such as illustrated inFIGS. 5-6 the pinion insert 60 will be formed as an annular hub havingan interior radial surface and an exterior radial surface. In certainembodiments, the interior radial surface may include one or more slotsor protrusions 62 extending longitudinally along the interior radialsurface. In addition, as will be described in more detail below, theexterior radial surface may include one or more gear elements 64 formedthereon, such that the pinion insert 60 is configured to act as a pinionfrom a rack and pinion assembly.

With reference to FIG. 2, when positioned with the carrier insert 42about the core rod 30, the pinion insert 60 may be spaced apart from thethread-forming portion 46 of the carrier insert 42, so as to present athread-forming cavity 66 between the thread forming portion 46 and theinterior radial surface of the pinion insert 60. The thread-formingcavity 66 may form a portion of the parison-forming cavity 34. As such,and as illustrated in FIGS. 3 and 4, molten resin injected into theparison-forming cavity 34 will flow into the thread-forming cavity 66 soas to form a neck portion of the parison 36 with a shape correspondingto the thread-forming portion 46 and the pinion insert 60. The resultingparison 36 will, thus, include internal threads 70 (in the form ofthreaded grooves) formed on the interior-surface of its neck portion, asis shown in FIGS. 4-5, with such internal threads 70 corresponding tothe threaded protrusion 48 from the carrier insert 60. In addition,resulting parison 36 will include longitudinal protrusions and/or slots72 formed on the exterior surface of the parison's 36 neck portion, asis shown in FIGS. 4-6, with such protrusions and/or slots 72corresponding to the slots and/or protrusions 62, respectively, of thepinion insert 60. Specifically, a slot 62 on the pinion insert 60 willform a protrusion 72 on the parison 36, while a protrusion 62 on thepinion insert 60 will form a slot 72 on the parison 36.

As will be described in more detail below, the slots and/or protrusions62 of the pinion insert 60 will be operable to engage a portion thecorresponding protrusions and/or slots 72 formed on the exterior surfaceof the neck portion of the parison 36, such that the pinion insert 60 isoperable to engage with and the parison 36 once the parison 36 has beenformed. Furthermore, embodiments provide for the pinion insert 60 torotate with respect to the remaining components of the carrier assembly40. Given that the pinion insert 60 is operable to be engaged with theparison via the slots and/or protrusion 62,72, a rotation of the pinioninsert 60 will cause a corresponding rotation of the parison 36.

Returning to FIGS. 2-3, in certain embodiments, the carrier assembly 40may further include a carrier plate 80 for securing the carrier insert42 and the pinion insert 60 in position about the core rod 30. In someembodiments, the carrier plate 80 may be used in conjunction with aretainer ring 82 for surrounding and securing the carrier insert 42 andthe pinion insert 60 in place. In some embodiments, as perhaps bestshown in FIGS. 5 and 6, each of the retainer ring 82 and the carrierinsert 42 and may include openings 83 for receiving fasteners (e.g.,threaded bolts) to secure the retainer ring and the carrier insert 42together, and in some embodiments, to the carrier plate 80. Withreference to FIG. 5, the retainer ring 82 may also include a flangeportion 84 for supporting at least a portion of the pinion insert 60against the carrier plate 80 to secure the pinion insert 60 in place.Furthermore, the retainer ring 82 may include one or more flat edgesections 86 on its exterior radial edge. As will be described in moredetail below, the flat edge sections 86 may facilitate the carrierinsert 42 to remain generally stationary, while the pinion insert 60 isbeing rotated. In some alternative embodiments, in place of the retainerring 82, the carrier plate 80 may include integral upper and lowerportions, which function in a manner similar to the combination of thecarrier plate 80 and the retainer ring 82 illustrated in the drawings.

Given the carrier assembly 40 used in conjunction with the core rod 30and the mold 32, as described above, the injection process may beperformed by injecting molten resin, such as PET or anotherthermoplastic resin, into the parison-forming cavity 34 cooperativelydefined by the core rod 30 and the mold 32. The resin is injected in aheated, molten form, such that it will fill the parison-forming cavity34, as shown in FIG. 3. The resin may remain within the parison-formingcavity 34 until it hardens to a point at which it can at leasttemporarily hold its shape in the form of a parison 36 when removed fromthe mold 32. As indicated above, embodiments of the present inventionprovide for a neck portion of the parison 36 to be formed with internalthreads 70. Such internal threads 70 are formed by way of the resin'smolding around the thread-forming portion 46 of the carrier insert 60.In particular, as the resin fills the thread-forming cavity 66 of theparison-forming cavity 34, which is presented between the thread-formingportion 46 of the carrier insert 42 and the pinion insert 60, the resinwill cool to form a neck of the parison 36, with such neck includinginternal threads 70.

Once the parison 36 has sufficiently cooled so as to retain its shape,the parison 36 will be transferred to the conditioning station 16 (forthe 4-stage ISBM machine) or to the stretch blow station 18 (for the3-stage ISBM machine). Embodiments of the present invention will providefor the parison 36 to be transferred via the carrier assembly 40 thatsecures the parison 36 by its neck portion. In particular, the core rod30, which was used at the injection station 12, will be removed suchthat the parison 36 will be supported between the carrier insert 42 andthe pinion insert 60 (with the carrier insert 42 and the pinion insert60 being supported by the carrier plate 80). Once transferred to theconditioning station 16 (if applicable), the parison 36 may undergovarious conditioning processes, such as heating, which will prepare theparison 36 for being properly stretch blow molded into a molded articleat the stretch blow station 18. From the conditioning station 16, theparison will be transferred to the stretch blow station 18 via thecarrier assembly 40. At the stretch blow station 18, the parison 36 willbe stretch blown to form the molded article. In particular, the stretchblow station 18 will insert a stretch rod into the parison 36, with thestretch rod being operable to provide radial and axial stretching to theparison 36 while air is simultaneously blown into the parison 36. Assuch, the parison will be stretch blown into a molded article, such asmolded article 90 shown in FIGS. 7 and 8, which corresponds to a moldcavity of the blow molds used at the stretch blow station 18.Beneficially, the final molded article 90 will include internal threads70 formed on its neck portion. As such, embodiments of the presentinvention include a stretch blow molded article 90 comprising a body anda neck extending from the body and presenting an opening for fluidlyconnecting an exterior of the molded article 90 to an interior of thebody. As shown in FIGS. 7 and 8, the neck includes an interior radialsurface an exterior radial surface, with the interior radial surfaceincluding threads 70 formed thereon. Corresponding with the threadedprotrusion 48 of the carrier insert 42, the threads 70 formed on theinterior radial surface of the neck may comprise double lead threads.Furthermore, to correspond with some embodiments of the threadedprotrusion 48 of the carrier insert 42, the threads 70 formed on theinterior surface of the molded article's 90 neck may have a lowermoststarting point and an uppermost ending point, with the lowermoststarting points being located on a plane that bisects the neck and thatinclude a longitudinal centerline of the neck. Further, the uppermostending points may extend along the molded article's 90 neck past theplane that includes said lowermost starting point.

Upon forming the molded article at the stretch blow station 18, themolded article will be transferred, via the carrier assembly 40, to theejection station 20. It is noted that the molded article 90 illustratedin FIGS. 7-8 is purely exemplary, and the molded articles formedaccording to embodiments of the present invention may be formed in anyshape required and as defined by the blow molds of the stretch blowstation 18.

In standard ISBM machines, the ejection station 20 generally comprises astripper plate, an ejection rod, or any other device configured forpushing, pulling, dumping, or otherwise stripping the molded articlefrom the thread splits and/or carrier plate once the molded article hasbeen blow molded. However, the molded article of embodiments of thepresent invention is threadedly secured to the carrier assembly 40between the carrier insert 42 and the pinion insert 60. As such, toeject the molded article, the molded article must be rotated such thatit is twisted off of the thread-forming portion 46 of the carrier insert42.

To accomplish such rotation of a molded article with internal threads70, such as molded article 90 shown in FIGS. 7-8, embodiments of thepresent invention include ejection station tooling 100 illustrated inFIGS. 9-14. With reference to FIG. 9, the ejection station tooling 100of embodiments of the present invention may comprise a base 102 and anactuation assembly 104 associated with the base 102 and operable toactuate certain components of the ejection station tooling 100, so aseject an internally-threaded molded article 90 that is engaged with thecarrier assembly 40. The actuation assembly 104 may comprise ahydraulic, a pneumatic, or an electromechanically-actuated actuatorcomponent 106 configured to actuate a plate 108 in a first dimension(e.g., a “Y” dimension directed vertically, such as upward anddownward), and a bar 110 configured to actuate in a second dimension(e.g., an “X” dimension directed horizontally, such as left and right)in response to the actuation of the plate 108. In some embodiments, thefirst and second dimensions will be orthogonal to each other. As such,the ejection station tooling 100 is operable to remove the moldedarticle 90 from the carrier assembly 40 by causing the molded article torotate with respect to a portion of the carrier assembly 40, as will bedescribed in more detail below.

In some embodiments, the plate 108, which is secured to the actuatorcomponent 106 of the ejection station tooling 100, may comprise a camplate. In particular, the cam plate 108 is operable to actuate in thefirst dimension in response to the actuation of the actuator component106. For instance, as the actuator component 106 actuates in a downwarddirection, the cam plate 108 will similarly actuate in the downwarddirection. With reference to FIGS. 9-10, the cam plate 108 may include agroove 112 extending through at least a portion of the cam plate's 108surface. Furthermore, as perhaps best shown in FIG. 11, the ejectionstation tooling 100 may further comprise a roller 114 rotatablyconnected to the bar 110 and operable to travel through the groove 112of the cam plate 108 in response to the actuation of the cam plate 108.In more detail, and with reference to FIG. 9, as the cam plate 108actuates in the first dimension (e.g., vertical), the roller 114 isconfigured to actuate through the groove 112, with such actuationincluding actuation in the second dimension (e.g., horizontal).Specifically, the groove 112 may comprise a first portion 116 and asecond portion 118. As the cam plate 108 is actuated downward, theroller 114 first actuates through the groove 112 in the directionindicated in FIG. 12, with the roller 114 initially travelling throughthe first portion 116 of the groove 112 and then through the secondportion 118 of the groove 112.

With reference to FIG. 12, the bar 110 of the ejection station tooling110 may comprises a rack with gear elements 120 formed thereon. Becausethe rack 110 is coupled with the roller 114, as the roller 114 actuatesthrough the groove 112 in the second dimension (e.g., horizontal), therack 110 correspondingly actuates in the second dimension. It should beunderstood that the rack 110 and the roller 114 are held secure in thefirst dimension (e.g., vertical) via the carrier plate 80 and via abottom plate 129 associated with the ejection station tooling 100. Assuch, although the rack 110 and roller 114 are capable of actuating inthe second dimension in response to the cam plate's 108 actuation in thefirst dimension, the rack 110 and roller 114 are restricted fromactuating in the first dimension. Given the components described above,the ejection station tooling 100 is operable to remove the moldedarticle that is engaged with the carrier assembly 40.

In more detail, and with reference to FIGS. 12-14, the gear elements 120of the rack 110 are configured to engage with the gear elements 64 (notshown in FIG. 12) of the pinion insert 60 of the carrier assembly 40.With cam plate 108 actuating in the first dimension (e.g., downward),and the roller 114 and the rack 110 actuating in the second dimension inresponse (e.g., left to right), the actuation of the rack 110 isoperable to cause a corresponding rotation of the pinion insert 60 ofthe carrier assembly 40. For instance, FIG. 13 illustrates the cam plate108 in an upper-most position, such that the roller 114 is positioned inthe first portion 116 of the groove 112 and the rack 110 is in aleft-most position. Alternatively, FIG. 14 illustrates the cam plate 108in a downward-most position, such that the roller 114 is positioned inthe second portion 118 of the groove 112 and the rack 110 is in aright-most position. During the actuation of the rack 110 from theleft-most to the right-most positions, the gear elements 120 of the rack110 engage with the gear elements 64 of the pinion insert, to therebycause the pinion insert 60 to rotate.

Furthermore, because the pinion insert 60 is engaged with the moldedarticle 90, via the slots and/or protrusions 62 on the pinion insert 60and the protrusions and/or slots 72, respectively, on the molded article90, rotation of the pinion insert 60 is operable to cause acorresponding rotation of the molded article 90. By providing asufficient rotation of the molded article 90, as shown in FIGS. 12-14,the molded article 90 will be twisted off the thread-forming portion 46of the carrier insert 42. Specifically, the molded article 90 will betwisted off the thread-forming portion 46 and will simultaneously beforced downward along the interior radial surface of the pinion insert60 (including along the slots and/or protrusions 62 formed thereon). Insome embodiments, once the molded article 90 has been separated from thethread-forming portion 46 of the carrier insert 42, the molded article90 will simply be allowed to fall downward, under the force of gravity,to be completely separated from the carrier assembly 40. In otherembodiments, once the molded article has been separated from thethread-forming portion 46 of the carrier insert 42, the molded articlecan be separated from the pinion insert 60 via other standard methodsand tooling, such as an ejection rod or any other device configured forpushing, pulling, dumping, or otherwise stripping the molded articlefrom the pinion insert 60. Regardless, the ejection station tooling 100described above provides for the molded article to be completely ejectedfrom the carrier assembly 40.

To facilitate the ability of the pinion insert 60 and the molded article90 to be rotated with respect to the carrier insert 42, as perhaps bestshown in FIG. 12, one of the flat edge sections 86 of the retainer ring82 can be aligned and positioned adjacent with a flanged upper portion122 of the rack 110, such that the retainer ring 82 is restricted fromrotating. Because the retainer ring 82 is coupled with the carrierinsert 42 via fasteners, the flat edge sections 86 is configured tofurther prevent the rotation of the carrier insert 42 during rotation ofthe pinion insert 60.

In some embodiments, the cam plate 108 may comprise a stripper platefrom a standard ISBM machine, which has been modified with the groove112. As was previously described, the groove 112 of the cam plate 108may comprise the first portion 116 and the second portion 118. The firstportion 116 may extend further in the first dimension (e.g., vertically)than in the second dimension (e.g., horizontally), the second portion118 may extends further in the second dimension than the firstdimension. As such, when the roller 114 travels through first portion116 of the groove 112, the rack 110 is operable to actuate in the seconddimension at a first speed, such that the pinion insert 60 is operableto rotate at a first rotation rate. Alternatively, with the roller 114travelling in said second portion 118 of the groove 112, the rack 110 isoperable to actuate in the second dimension at a second speed, such thatthe pinion insert 60 is operable to rotate at a second rotation rate. Assuch, ejection station 20 provides for the molded article 90 toinitially be rotated slowly when being removed from the carrier assembly40, so as to avoid any breakages or interferences that may result from aquick initial rotation. Once the molded article 90 begins to rotate, therotation rate can be increased so as to quickly eject the molded article90 from the carrier assembly 40.

Although the invention has been described with reference to thepreferred embodiment illustrated in the attached drawing figures, it isnoted that equivalents may be employed and substitutions made hereinwithout departing from the scope of the invention as recited in theclaims. For example, in some embodiments, such as illustrated in FIGS.15-16, an additional embodiment of a carrier assembly 130 may includeone or more bearing-type elements 132, such as a bearing sleeve and/or aplurality of roller bearings, positioned between a carrier insert 134and a pinion insert 136 so as to facilitate rotation of the pinioninsert 136 about the carrier insert 134.

Embodiments of the present invention may include other variations ofejection station tooling for ejecting internally-threaded parisons ormolded articles 90 from an ISBM machine 10. For example, FIGS. 17-22illustrate ejection station tooling 200 that may be incorporated as partof an ISBM machine 10. As with the previously-described ejection stationtooling 100, the ejection station tooling 200 may be used to ejectparisons or articles 90 having internal threads.

In more detail, and remaining with FIGS. 17-21, the ejection stationtooling 200 may comprise a base 202 and an actuation assembly 204associated with the base 202 and operable to shift or otherwise actuatecertain components of the ejection station tooling 200. As such, theejection station tooling 200 may eject internally-threaded moldedarticles 90 that are engaged with carrier assemblies, such as carrierassemblies 40, 130 described above. In more detail, the actuationassembly 204 may comprise a hydraulic, a pneumatic, or anelectromechanically-actuated actuator component 206 that is configuredto vertically shift a drive mechanism 208 upward and downward. In someembodiments, the drive mechanism 208 may comprise a rotating actuator ordriver configured to rotate a bit tip 210 (See FIG. 20). The drivemechanism 208 may be electrically-powered via an electric motor 212 (SeeFIGS. 20 and 21). However, it should be understood that the drivemechanism 208 may be powered by other power sources, such as pneumatic,hydraulic, or mechanical power sources.

The ejection station tooling 200 is configured to eject one or moreinternally-threaded molded articles 90 from the injection stretch blowmolding machine 10 by causing the articles 90 to be rotated out ofengagement with their respective carrier assembly 130. Such rotation maybe facilitated via a rotation assembly 220 (See FIGS. 19-22) associatedwith and/or integrated within the carrier plate 80 that supports thecarrier assemblies 130. In some embodiments, the rotation assembly 220may form part of, or otherwise be considered part of, the actuationassembly 204. In more detail, as illustrated in FIGS. 18-21, the carrierplate 80 may comprise an upper portion 230 and a lower portion 232,which are configured to secure a row of one or more carrier assemblies130. As shown in the drawings, in some embodiments, a row may include atleast four carrier assemblies 130. The carrier plate 80 will generallybe secured to the rotation plate 240, such that the carrier assemblies130 can be rotated to each of the stations of the ISBM machine 10.

To remove the molded articles 90 from their respective carrier assembly130, the rotation assembly 220 of the ejection station tooling 200 canbe used to rotate the molded articles 90 such that they are disengagedwith the carrier assemblies 130. As shown in FIG. 23, some embodimentsmay provide for each of the molded articles 90 to be secured to acarrier assembly 130, which as described previously, includes arotatable pinion insert 136 separated from a carrier insert 134 by abearing-type element 132. The carrier insert 134 is generally configuredto be secured in a rigid manner to the carrier plate 80 (See FIG. 24).As such, the pinion insert 136 is free to rotate with respect to thecarrier insert 134 and the carrier plate 80. The pinion insert 136 mayinclude gear elements on its exterior radial surface, from whichrotation can be imparted to the pinion insert 136, as will be discussedin more detail below. Furthermore, as was discussed previously forcarrier assemblies 40, 130, the interior surface of the pinion insert136 can include slots and/or protrusions, which can be used torespectively create protrusions and/or slots on the necks of theparison, and on the resulting article (e.g., molded article 90). As aresult of the corresponding slots and protrusions, a rotation of thepinion insert 136 is configured to cause a corresponding rotation of theparison and/or molded article 90. Thus, with reference to FIG. 24, byrotating the pinion insert 136, an internally-threaded molded article 90can be rotated out of engagement with the threaded protrusion 48 of thecarrier insert 134 so as to be ejected from the carrier assembly 130and, more generally, from the ISBM machine 10.

Turning back to FIGS. 19-22, some embodiments provide for the rotationassembly 220 to comprise a plurality of spur gears 250 engaged with thepinion inserts 136 of the carrier assemblies 130 held within the carrierplate 80. In particular, embodiments may provide for individual spurgears 250 to be positioned between each pair of adjacent carrierassemblies 130 such that one of the spur gears 250 can simultaneouslyengage with the pinion inserts 136 of adjacent carrier inserts 130. Assuch, the number of spur gears 250 required for the rotation assembly220 may be dependent on the number of carrier assemblies 130 includedwithin the carrier plate 80. For instance, as illustrated in FIGS.19-22, embodiments that include four carrier assemblies 130 may requirethree spur gears 250. Additional carrier assemblies 130 may require acorresponding number of additional spur gears for operation.

In such a configuration, rotation of one of the spur gears 250 can causea corresponding rotation of each of the other spur gears 250 and of eachof the pinion inserts 136 to which the spur gears 250 are engaged. Forinstance, as illustrated in FIGS. 20-21, a center one of the spur gears250 may be rotated so as to cause a rotation of the pinion inserts 136of the center pair of carrier assemblies 130 included within the carrierplate 80. Such pinion inserts 136 may include spur-type gear element ontheir outer/exterior surfaces, which match the gear elements of the spurgears 250. The center spur gear 250 may be rotated via the drivemechanism 208. Specifically, a top surface of the center spur gear 250may include a female-mating surface that corresponds with the bit tip210 of the drive mechanism 208. As such, the drive mechanism 208 can bevertically shifted (e.g., lowered) into engagement with the center spurgear 250 to cause rotation of the center spur gear 250. Rotation of thepinion inserts 136 of the center two carrier assemblies 130 will cause acorresponding rotation of the outer two spur gears 250 that are engagedtherewith. Finally, rotation of the outer two spur gears 250 will causea rotation of the pinion inserts 136 of the outer carrier assemblies130.

Given the configuration described above, the ejection station tooling200 may be used to remove internally-threaded molded articles 90 fromcarrier assemblies 130. Specifically, the actuator component 206 of theactuation assembly 204 may vertically shift the drive mechanism 208downward into engagement with the center spur gear 250. At such time,the drive mechanism 208 may be energized so as to rotate the bit tip 210and the center spur gear 250 to which it is engaged. As was describedabove, rotation of the center spur gear 250 will cause a correspondingrotation of the remaining spur gears 250 and of each of the pinioninserts 136 of the carrier assemblies 130 included within the carrierplate 80. As illustrated by FIG. 22, rotation of the pinion inserts 136will cause the internally-threaded molded articles 90 to be rotated outof engagement with the threaded protrusions 48 (See FIG. 24) of thecarrier insert 134 so that the articles 90 can be removed from thecarrier assemblies 130 and ejected from the ISBM machine 10.

In addition to the embodiments of the ejection station tooling 200 shownin FIGS. 19-22, certain embodiments of the present invention may alsoinclude a rotation assembly 260 in the form of a helical gear 270 and aworm gear 280 embedded within the carrier plate 80, as illustrated inFIGS. 25-27. In some embodiments, the rotation assembly 260 may formpart of, or otherwise be considered part of, the actuation assembly 204.In more detail, the rotation assembly 260 may comprise the helical gear270, which is positioned generally centered with respect to the carrierplate 80. The helical gear 270 may be similar to the central spur gear250 described above, in that a top surface may include a female-matingsurface that is configured for engagement with the bit tip 210 of thedrive mechanism 208, as is shown in FIG. 25. As such, the drivemechanism 208 can be caused to impart rotation to the helical gear 270.

The helical gear 270 may be engaged with a portion of the worm gear 280so as to impart rotation to the worm gear 280. As illustrated in FIGS.26 and 27, the worm gear 280 may comprise an elongated shaft with aplurality of worm gear sections 282 positioned along the length of theshaft. In some embodiments, a central worm gear section 282 may bepositioned near a center of the worm gear 280, such that the helicalgear 270 can be engaged with the central worm gear section 282 and can,thus, impart rotation to the worm gear 280. The worm gear 280 mayinclude an additional worm gear section 282 for each of the carrierassemblies 130. Such additional worm gear sections 282 are generallyaligned with each of the carrier assemblies 130. As such, the worm gear280 extends along a length that is sufficient to extend across each ofthe carrier assemblies 130. Each of the additional worm gear sections282 may be engaged with the pinion inserts 136 of the carrier inserts130, such that rotation of the worm gear 280 can cause a correspondingrotation of the pinion inserts 136. In such embodiments, theouter/exterior surface of the pinion inserts 136 may be formed withhelical gear elements that are configured to engage with the worm gearsections 202.

In such a configuration, the rotation assembly 260 embodiments of theejection station tooling 200 may be used to remove internally-threadedmolded articles 90 from carrier assemblies 130. Specifically, asillustrated in FIG. 25, the actuator component 206 of the actuationassembly 204 may vertically shift the drive mechanism 208 downward intoengagement with the helical gear 270. At such time, the drive mechanism208 may be energized so as to rotate the bit tip 210 and the helicalgear 270 to which the bit tip 210 is engaged. As was described above,rotation of the helical gear 270 will cause a corresponding rotation ofthe worm gear 280 and each of the worm gear sections 282 includedthereon. As the worm gear sections 282 are engaged with the pinioninserts 136 of the carrier assemblies 130 included within the carrierplate 80, rotation of the worm gear 280 will, thus, cause a rotation ofthe pinion inserts 136. Finally, rotation of the pinion inserts 136 willcause the internally-threaded molded articles 90, as illustrated in FIG.27, to be rotated out of engagement with the threaded protrusions of thecarrier insert 134 so that the articles 90 can be removed from thecarrier assemblies 130 and ejected from the injection stretch blowmolding machine 10.

Although the invention has been described with reference to thepreferred embodiment illustrated in the attached drawing figures, it isnoted that equivalents may be employed and substitutions made hereinwithout departing from the scope of the invention as recited in theclaims.

The invention claimed is:
 1. Ejection station tooling for an injectionstretch blow molding machine, said ejection station tooling comprising:a carrier plate; a plurality of carrier assemblies secured to saidcarrier plate, each of said carrier assemblies configured to carry aninternally-threaded molded article; and an actuation assembly configuredto remove each of the molded articles from its respective carrierassembly by causing the molded article to rotate with respect to aportion of its carrier assembly, wherein each of said carrier assembliescomprises a carrier insert and a pinion insert, with said carrier insertand said pinion insert configured to cooperatively secure one of theinternally-threaded molded articles therebetween, wherein said carrierinsert includes a thread-forming portion configured to form internalthreads on a respective molded article, and wherein rotation of saidpinion insert is configured to cause a corresponding rotation therespective molded article.
 2. The ejection station tooling of claim 1,wherein said actuation assembly comprises a plurality of spur gearsintegrated within at least a portion of said carrier plate.
 3. Theejection station tooling of claim 2, wherein an exterior surface of eachof said pinion inserts includes gear elements formed thereon, whereinsaid spur gears are configured to engage with said gear elements of saidpinion inserts, such that rotation of said spur gears is configured tocause a corresponding rotation of said pinion inserts.
 4. The ejectionstation tooling of claim 3, wherein rotation of said pinion inserts isconfigured to disengage the internally-threaded molded articles from thecarrier inserts, so as to eject the internally-threaded molded articlesfrom the injection stretch blow molding machine.
 5. The ejection stationtooling of claim 2, wherein said actuation assembly comprises a drivemechanism configured to be shifted into engagement with one of said spurgears so as to impart rotation to each of said spur gears and to each ofsaid pinion inserts.
 6. The ejection station tooling of claim 5, whereinsaid drive mechanism comprises an electrically-powered driver.
 7. Theejection station tooling of claim 1, wherein said actuation assemblycomprises a worm gear integrated within at least a portion of saidcarrier plate.
 8. The ejection station tooling of claim 7, wherein anexterior surface of each of said pinion inserts includes gear elementsformed thereon, wherein said worm gear comprise a plurality of worm gearsections, wherein said worm gear sections are configured to engage withsaid gear elements of said pinion inserts, such that rotation of saidworm gear is configured to cause a corresponding rotation of said pinioninserts.
 9. The ejection station tooling of claim 8, wherein saidactuation assembly further comprises a helical gear engaged with one ofsaid worm gear sections and configured to impart rotation to said wormgear.
 10. The ejection station tooling of claim 1, wherein saidactuation assembly comprises a cam plate with a groove extending throughat least a portion of said cam plate, and a roller configured to actuatethrough said groove of said cam plate as said cam plate is verticallyshifted, wherein said roller is engaged with a rack with gears elementsformed thereon.
 11. The ejection station tooling of claim 10, whereinsaid rack is configured to engage with said pinion inserts of saidcarrier assemblies, wherein a downward shifting of said cam plate isconfigured to actuate said rack and to impart rotation to said pinioninserts so as to eject the internally-threaded molded articles from theinjection stretch blow molding machine.
 12. Ejection station tooling foran injection stretch blow molding machine, said ejection station toolingcomprising: a carrier plate; a plurality of carrier assemblies securedto said carrier plate, each of said carrier assemblies configured tocarry an internally-threaded molded article; and a rotation assemblyintegrated with said carrier plate, wherein said rotation assembly isconfigured to remove each of the molded articles from its respectivecarrier assembly by causing the molded article to rotate with respect toa portion of its carrier assembly, wherein each of said carrierassemblies comprises a carrier insert and a pinion insert, with saidcarrier insert and said pinion insert configured to cooperatively secureone of the internally-threaded molded articles therebetween, and whereinsaid pinion insert includes protrusions or slots for engagement with arespective molded article such that rotation of said pinion insert isconfigured to cause a corresponding rotation the respective moldedarticle.
 13. The ejection station tooling of claim 12, where saidrotation assembly comprises a plurality of spur gears at least partiallyintegrated with said carrier plate.
 14. The ejection station tooling ofclaim 12, where said rotation assembly comprises a worm gear at leastpartially integrated with said carrier plate.
 15. The ejection stationtooling of claim 12, further comprising a drive mechanism configured tobe shifted into engagement with said rotation assembly and to impartrotation to said rotation assembly.
 16. A method of ejecting aninternally-threaded molded article from an injection stretch blowmolding machine, wherein injection stretch blow molding machine includesa carrier assembly comprising a carrier insert and a pinion insert, withthe carrier insert and the pinion insert configured to cooperativelysecure the molded article therebetween, wherein the carrier insertincludes a thread-forming portion configured to form internal threads onthe molded article, said method comprising the steps of: (a) shifting adrive mechanism into engagement with a rotation assembly; (b) causingone or more components of said rotation assembly to rotate; (c)imparting rotation from the rotation assembly to the pinion insert ofthe carrier assembly, wherein during said imparting of step (c), themolded article is disengaged from the carrier assembly by the pinioninsert causing the molded article to rotate with respect to the carrierinsert of the carrier assembly.
 17. The method claim 16, where saidrotation assembly comprises a plurality of spur gears at least partiallyintegrated with a carrier plate that supports the carrier assembly. 18.The method claim 16, where said rotation assembly comprises a worm gearat least partially integrated with a carrier plate that supports thecarrier assembly.
 19. The method of claim 16, wherein the carrierassembly transports the carrier assembly and the internally-threadedmolded article from a stretch blow station of the injection stretch blowmolding machine to the ejection station.